Transcript Chapter 3

Chapter 24
The Digestive System
Lecture Outline
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INTRODUCTION
• Food contains substances and energy the body needs to
construct all cell components. The food must be broken
down through digestion to molecular size before it can be
absorbed by the digestive system and used by the cells.
• The organs that collectively perform these functions
compose the digestive system.
• The medical professions that study the structures, functions,
and disorders of the digestive tract are gastroenterology for
the upper end of the system and proctology for the lower
end.
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Chapter 24
The Digestive System
• Structure
– Gross Anatomy
– Histology
• Function
– Mechanical
– Chemical
• Development
• Disorders
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OVERVIEW OF THE DIGESTIVE SYSTEM
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Overview of GI tract Functions
• Mouth---bite, chew, swallow
• Pharynx and esophagus----transport
• Stomach----mechanical disruption;
absorption of water & alcohol
• Small intestine--chemical &
mechanical digestion & absorption
• Large intestine----absorb electrolytes
& vitamins (B and K)
• Rectum and anus---defecation
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Organization
• The two major sections of the digestive system perform the
processes required to prepare food for use in the body
(Figure 24.1).
• The gastrointestinal tract is the tube open at both ends for
the transit of food during processing. The functional
segments of the GI tract include the mouth, esophagus,
stomach, small intestine, and large intestine.
• The accessory structures that contribute to the food
processing include the teeth, tongue, salivary glands, liver,
gallbladder, and pancreas.
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Digestion
• Digestion includes six basic processes.
• Ingestion is taking food into the mouth (eating).
• Secretion is the release, by cells within the walls of the GI tract and
accessory organs, of water, acid, buffers, and enzymes into the lumen of
the tract.
• Mixing and propulsion result from the alternating contraction and
relaxation of the smooth muscles within the walls of the GI tract.
• Digestion
• Mechanical digestion consists of movements of the GI tract that aid
chemical digestion.
• Chemical digestion is a series of catabolic (hydrolysis) reactions that
break down large carbohydrate, lipid, and protein food molecules into
smaller molecules that are usable by body cells.
• Absorption is the passage of end products of digestion from the GI tract
into blood or lymph for distribution to cells.
• Defecation is emptying of the rectum, eliminating indigestible
substances from the GI tract.
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LAYERS OF THE GI TRACT
• The basic arrangement of layers in the gastrointestinal tract
from the inside outward includes the mucosa, submucosa,
muscularis, and serosa (visceral peritoneum) (Figure 24.2).
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Layers of the GI Tract
1. Mucosal layer
2. Submucosal layer
3. Muscularis layer
4. Serosa layer
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Mucosa
• Epithelium
– stratified squamous(in mouth,esophagus & anus) = tough
– simple columnar in the rest
• secretes enzymes and absorbs nutrients
• specialized cells (goblet) secrete mucous onto cell surfaces
• enteroendocrine cells---secrete hormones controlling organ
function
• Lamina propria
– thin layer of loose connective tissue
– contains BV and lymphatic tissue
• Muscularis mucosae---thin layer of smooth muscle
– causes folds to form in mucosal layer
– increases local movements increasing absorption with exposure to
“new” nutrients
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LAYERS OF THE GI TRACT
• The submucosa consists of aerolar connective tissue. It is
highly vascular, contains a part of the submucosal plexus
(plexus of Meissner), and contains glands and lymphatic
tissue.
• The submucosal plexus is a part of the autonomic nervous
system.
• It regulates movements of the mucosa, vasoconstriction of
blood vessels, and innervates secretory cells of mucosal
glands.
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Submucosa
• Loose connective tissue
– containing BV, glands
and lymphatic tissue
• Meissner’s plexus--– parasympathetic
– innervation
• vasoconstriction
• local movement by
muscularis mucosa
smooth muscle
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Enteric Nervous System
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Muscularis
• Skeletal muscle = voluntary control
– in mouth, pharynx , upper esophagus and anus
– control over swallowing and defecation
• Smooth muscle = involuntary control
– inner circular fibers & outer longitudinal fibers
– mixes, crushes & propels food along by peristalsis
• Auerbach’s plexus (myenteric)-– both parasympathetic & sympathetic innervation of circular
and longitudinal smooth muscle layers
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Serosa
• An example of a serous membrane
• Covers all organs and walls of cavities not open to the
outside of the body
• Secretes slippery fluid
• Consists of connective tissue covered with simple
squamous epithelium
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NEURAL INNERVATION OF THE GI TRACT
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Enteric Nervous System
• ENS consists of neurons that extend from the esophagus to
the gut (Figure 24.2)
• Located in the myenteric plexus and the submucosal plexus.
• Consists of motor neurons, interneurons, and sensory
neurons (Figure 24.3)
• Myenteric neurons control gastric motility while the
submucosal neurons control the secretory cells.
• Can function independently of the CNS
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Enteric Nervous System
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Autonomic Nervous System (ANS)
• Vagus nerve (X) supplies parasympathetic fibers. These
fibers synapse with neurons in the ENS and increase their
action.
• Sympathetic nerves arise from the thoracic and upper
lumber regions of the spinal cord. These fibers also
synapse with neurons in the ENS. However, they inhibit the
ENS neurons.
• Gastrointestinal Reflex Pathways
– Regulate secretions and motility in response to stimuli
present in the lumen.
– The reflexes begin with receptors associated with
sensory neurons of the ENS.
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Peritoneum
• Peritoneum
– visceral layer covers
organs
– parietal layer lines the
walls of body cavity
• Peritoneal cavity
– potential space
containing a bit of
serous fluid
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Parts of the Peritoneum
•
•
•
•
•
Mesentery
Mesocolon
Lesser omentum
Greater omentum
Peritonitis = inflammation
– trauma
– rupture of GI tract
– appendicitis
– perforated ulcer
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Greater Omentum, Mesentery & Mesocolon
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Lesser Omentum
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Clinical Application
• Peritonitis is an acute inflammation of the peritoneum.
• Cause
– contamination by infectious microbes during surgery or
from rupture of abdominal organs
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MOUTH
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Introduction
• The mouth (oral or buccal cavity) is formed by the cheeks,
hard and soft palate, lips, and tongue (Figure 24.5).
• The vestibule of the oral cavity is bounded externally by the
cheeks and lips and internally by the gums and teeth.
• The oral cavity proper is a space that extends from the
gums and teeth to the fauces, the opening between the oral
cavity and the pharynx or throat.
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Mouth
• Lips and cheeks-----contains buccinator muscle that keeps food between
upper & lower teeth
• Vestibule---area between cheeks and teeth
• Oral cavity proper---the roof = hard, soft palate and uvula
– floor = the tongue
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Pharyngeal Arches
• Two skeletal muscles
• Palatoglossal muscle
– extends from palate to
tongue
– forms the first arch
– posterior limit of the mouth
• Palatopharyngeal muscle
– extends from palate to
pharyngeal wall
– forms the second arch
– behind the palatine tonsil
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Salivary
Glands
•
•
•
•
Parotid below your ear and over the masseter
Submandibular is under lower edge of mandible
Sublingual is deep to the tongue in floor of mouth
All have ducts that empty into the oral cavity
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Composition and Functions of Saliva
• Wet food for easier swallowing
• Dissolves food for tasting
• Bicarbonate ions buffer acidic foods
– bulemia---vomiting hurts the enamel on your teeth
• Chemical digestion of starch begins with enzyme (salivary
amylase)
• Enzyme (lysozyme) ---helps destroy bacteria
• Protects mouth from infection with its rinsing action---1 to 1
and 1/2qts/day
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Salivary Gland Cellular Structure
• Cells in acini (clusters)
• Serous cells secrete a watery fluid
• Mucous cells (pale staining) secrete a slimy, mucus secretion
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Salivation
• Increase salivation
– sight, smell, sounds, memory of food, tongue
stimulation---rock in mouth
– cerebral cortex signals the salivatory nuclei in
brainstem---(CN 7 & 9)
– parasympathetic nn. (CN 7 & 9)
• Stop salivation
– dry mouth when you are afraid
– sympathetic nerves
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Mumps
• Myxovirus that attacks the parotid gland
• Symptoms
– inflammation and enlargement of the parotid
– fever, malaise & sour throat (especially swallowing
sour foods)
– swelling on one or both sides
• Sterility rarely possible in males with testicular
involvement (only one side involved)
• Vaccine available since 1967
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Structure and Function of the Tongue
• The tongue, together with its associated muscle, forms the
floor of the oral cavity. It is composed of skeletal muscle
covered with mucous membrane.
• Extrinsic and intrinsic muscles permit the tongue to be
moved to participate in food manipulation for chewing and
swallowing and in speech.
• The lingual frenulum is a fold of mucous membrane that
attaches to the midline of the undersurface of the tongue.
• The upper surface and sides of the tongue are covered with
papillae. Some papillae contain taste buds .
• On the dorsum of the tongue are glands that secrete lingual
lipase, which initiates digestion of triglycerides.
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Structure and Function of the Tongue
• Muscle of tongue is
attached to hyoid,
mandible, hard palate
and styloid process
• Papillae are the bumps--taste buds are protected
by being on the sides of
papillae
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Structure and Function of the Teeth
• The teeth project into the mouth and are adapted for mechanical
digestion (Figure 24.7).
• A typical tooth consists of three principal portions: crown, root, and neck.
• Teeth are composed primarily of dentin, a calcified connective tissue that
gives the tooth its basic shape and rigidity; the dentin of the crown is
covered by enamel, the hardest substance in the body, which protects
the tooth from the wear of chewing.
• The dentin of the root is covered by cementum, another bone-like
substance, which attaches the root to the periodontal ligament (the
fibrous connective tissue lining of the tooth sockets in the mandible and
maxillae).
• The dentin encloses the pulp cavity in the crown and the root canals in
the root.
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Tooth Structure
•
•
•
•
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Crown
Neck
Roots
Pulp cavity
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Composition of Teeth
• Enamel
– hardest substance in
body
– calcium phosphate or
carbonate
• Dentin
– calcified connective
tissue
• Cementum
– bone-like
– periodontal ligament
penetrates it
What is the gingiva?
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Dentition
• There are two dentitions, or sets of teeth, in an individual’s
lifetime: deciduous (primary), milk teeth, or baby teeth; and
permanent (secondary) teeth (Figure 24.8 a,b).
• Primary or baby teeth
– 20 teeth that start erupting at 6 months
– 1 new pair of teeth per month
• Permanent teeth
– 32 teeth that erupt between 6 and 12 years of age
– differing structures indicate function
• incisors for biting
• canines or cuspids for tearing
• premolars & molars for crushing and grinding food
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Dentistry
• In root canal therapy all traces of pulp tissue are removed
from the pulp cavity and root canal of a badly diseased tooth
• The branch of dentistry that is concerned with the
prevention, diagnosis, and treatment of diseases that affect
the pulp, root, periodontal ligament, and alveolar bone is
known as endodontics.
• Orthodontics is a dental branch concerned with the
prevention and correction of abnormally aligned teeth.
• Periodontics is a dental branch concerned with the
treatment of abnormal conditions of tissues immediately
around the teeth.
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Primary and Secondary Dentition
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Digestion in the Mouth
• Table 24.1 summarizes digestion in the mouth.
• Mechanical digestion (mastication or chewing)
• breaks into pieces
• mixes with saliva so it forms a bolus
• Chemical digestion
– amylase
• begins starch digestion at pH of 6.5 or 7.0 found in mouth
• when bolus & enzyme hit the pH 2.5 gastric juices hydrolysis
ceases
– lingual lipase
• secreted by glands in tongue
• begins breakdown of triglycerides into fatty acids and glycerol
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PHARYNX
• The pharynx is a funnel-shaped tube that extends from the
internal nares to the esophagus posteriorly and the larynx
anteriorly (Figure 24.4).
• It is composed of skeletal muscle and lined by mucous
membrane.
• The nasopharynx functions in respiration only, whereas the
oropharynx and laryngopharynx have digestive as well as
respiratory functions.
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Pharynx
• Funnel-shaped tube extending from internal nares to the
esophagus (posteriorly) and larynx (anteriorly)
• Skeletal muscle lined by mucous membrane
• Deglutition or swallowing is facilitated by saliva and mucus
– starts when bolus is pushed into the oropharynx
– sensory nerves send signals to deglutition center in
brainstem
– soft palate is lifted to close nasopharynx
– larynx is lifted as epiglottis is bent to cover glottis
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ESOPHAGUS
• The esophagus is a collapsible, muscular tube that lies
behind the trachea and connects the pharynx to the
stomach (Figure 24.1).
• The wall of the esophagus contains mucosa, submucosa,
and muscularis layers. The outer layer is called the
adventitia rather than the serosa due to structural
differences (Figure 24.9).
• The role of the esophagus is to secrete mucus and transport
food to the stomach.
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Esophagus
•
•
•
•
•
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Collapsed muscular tube
In front of vertebrae
Posterior to trachea
Posterior to the heart
Pierces the diaphragm at
hiatus
– hiatal hernia or
diaphragmatic hernia
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Histology of the Esophagus
• Mucosa = stratified squamous
• Submucosa = large mucous
glands
• Muscularis = upper 1/3 is skeletal,
middle is mixed, lower 1/3 is
smooth
– upper & lower esophageal
sphincters are prominent
circular muscle
• Adventitia = connective tissue
blending with surrounding
connective tissue--no peritoneum
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DEGLUTITION
• Moves a bolus from the mouth to the stomach. It is facilitated by saliva
and mucus and involves the mouth, pharynx, and tongue (Figure 24.10).
– It consists of a voluntary stage, pharyngeal stage (involuntary) and
esophageal stage.
• Voluntary stage begins when the bolus is forced into the oropharynx by
tongue movement.
• Receptors in the oropharyns stimulate the deglutition center in the
medulla. This begins the pharyngeal stage which moves food from the
pharynx to the esophagus.
• The esophageal stage begins when the bolus enters the esophagus.
During this stage the peristalsis movers the bolus from the esophagus to
the stomach.
• Table 24.2 summarizes the digestion related activities of the pharynx
and esophagus.
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Physiology of the Esophagus - Swallowing
• Voluntary phase---tongue pushes food to back of oral cavity
• Involuntary phase----pharyngeal stage
– breathing stops & airways are closed
– soft palate & uvula are lifted to close off nasopharynx
– vocal cords close
– epiglottis is bent over airway as larynx is lifted
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Swallowing
• Upper sphincter relaxes when larynx is
lifted
• Peristalsis pushes food down
– circular fibers behind bolus
– longitudinal fibers in front of
bolus shorten the distance
of travel
• Travel time is 4-8 seconds for solids and 1 sec for liquids
• Lower sphincter relaxes as food approaches
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Gastroesophageal Reflex Disease
• If lower sphincter fails to open
– distension of esophagus feels like chest pain or heart attack
• If lower esophageal sphincter fails to close
– stomach acids enter esophagus & cause heartburn (GERD)
– for a weak sphincter---don't eat a large meal and lay down in
front of TV
– smoking and alcohol make the sphincter relax worsening the
situation
• Control the symptoms by avoiding
– coffee, chocolate, tomatoes, fatty foods, onions & mint
– take Tagamet HB or Pepcid AC 60 minutes before eating
– neutralize existing stomach acids with Tums
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STOMACH
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Introduction
• The stomach is a J-shaped enlargement of the GI tract that
begins at the bottom of the esophagus and ends at the
pyloric sphincter (Figure 24.11).
• It serves as a mixing and holding area for food, begins the
digestion of proteins, and continues the digestion of
triglycerides, converting a bolus to a liquid called chyme. It
can also absorb some substances.
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Anatomy of the Stomach
• The gross anatomical subdivisions of the stomach include
the cardia, fundus, body, and pyloris (Figure 24.11).
• When the stomach is empty, the mucosa lies in folds called
rugae.
• Pylorospasm and pyloric stenosis are two abnormalities of
the pyloric sphincter that can occur in newborns. Both
functionally block or partially block the exit of food from the
stomach into the duodenum and must be treated with drugs
or surgery (Clinical Application).
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Anatomy of the Stomach
• At the greater curvature, the visceral peritoneum becomes
the greater omentum.
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Anatomy of Stomach
• Which side is it on?
• Size when empty?
– large sausage
– stretches due to rugae
• Parts of stomach
– cardia
– fundus---air in x-ray
– body
– pylorus---starts to
narrow as approaches
pyloric sphincter
• Empties as small squirts of
chyme leave the stomach
through the pyloric valve
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Anatomy of Stomach
• Which side is it on?
• Size when empty?
– large sausage
– stretches due to rugae
• Parts of stomach
– cardia
– fundus---air in x-ray
– body
– pylorus---starts to
narrow as approaches
pyloric sphincter
• Empties as small squirts of
chyme leave the stomach
through the pyloric valve
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Pylorospasm and Pyloric Stenosis
• Abnormalities of the pyloric sphincter in infants
• Pylorospasm
– muscle fibers of sphincter fail to relax trapping
food in the stomach
– vomiting occurs to relieve pressure
• Pyloric stenosis
– narrowing of sphincter indicated by projectile
vomiting
– must be corrected surgically
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Histology of the Stomach
• The surface of the mucosa is a layer of simple columnar epithelial cells
called mucous surface cells (Figure 24.12a).
• Epithelial cells extend down into the lamina propria forming gastric pits
and gastric glands.
• The gastric glands consist of three types of exocrine glands: mucous
neck cells (secrete mucus), chief or zymogenic cells (secrete
pepsinogen and gastric lipase), and parietal or oxyntic cells (secrete
HCl).
• Gastric glands also contain enteroendocrine cells which are hormone
producing cells. G cells secrete the hormone gastrin into the
bloodstream.
• Zollinger-Ellison Syndrome is a syndrome in which an individual
produces too much HCl. It is caused by excessive gastrin which
stimulates the secretion of gastric juice.
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Histology of the Stomach
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Mucosa & Gastric Glands
• Hydrochloric acid converts pepsinogen
from chief cell to pepsin
• Intrinsic factor
– absorption of vitamin B12 for RBC
production
• Gastrin hormone (g cell)
– “get it out of here”
• release more gastric juice
• increase gastric motility
• relax pyloric sphincter
• constrict esophageal sphincter
preventing entry
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Mucosa of the Fundus
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Histology of the Stomach
• The submucosa is composed of areolar connective tissue.
• The muscularis has three layers of smooth muscle:
longitudinal, circular, and an inner oblique layer.
• The serosa is a part of the visceral peritoneum.
• At the lesser curvature, the visceral peritoneum becomes
the lesser omentum.
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Submucosa
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Muscularis
• Three layers of smooth
muscle--outer
longitudinal, circular &
inner oblique
• Permits greater
churning & mixing of
food with gastric juice
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Serosa
• Simple squamous epithelium over a bit of connective tissue
• Also known as visceral peritoneum
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Physiology--Mechanical Digestion
• Gentle mixing waves
– every 15 to 25 seconds
– mixes bolus with 2 quarts/day of gastric juice to
turn it into chyme (a thin liquid)
• More vigorous waves
– travel from body of stomach to pyloric region
• Intense waves near the pylorus
– open it and squirt out 1-2 teaspoons full with each
wave
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Physiology--Chemical Digestion
• Protein digestion begins
– HCl denatures (unfolds) protein molecules
– HCl transforms pepsinogen into pepsin that breaks
peptides bonds between certain amino acids
• Fat digestion continues
– gastric lipase splits the triglycerides in milk fat
• most effective at pH 5 to 6 (infant stomach)
• HCl kills microbes in food
• Mucous cells protect stomach walls from being digested
with 1-3mm thick layer of mucous
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Gastric pH
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Application
• Vomiting is the forcible expulsion of the contents of the
upper GI tract (stomach and sometimes duodenum) through
the mouth. Prolonged vomiting, especially in infants and
elderly people, can be serious because the loss of gastric
juice and fluids can lead to disturbances in fluid and acidbase balance
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PANCREAS
• The pancreas is divided into a head, body, and tail and is
connected to the duodenum via the pancreatic duct (duct of
Wirsung) and accessory duct (duct of Santorini) (Figure
24.14).
• Pancreatic islets (islets of Langerhans) secrete hormones
and acini secrete a mixture of fluid and digestive enzymes
called pancreatic juice (Figure 18.23).
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Anatomy of the
Pancreas
•
•
•
•
•
5" long by 1" thick
Head close to curve in C-shaped duodenum
Main duct joins common bile duct from liver
Sphincter of Oddi on major duodenal papilla
Opens 4" below pyloric sphincter
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Pancreatic Duct
• Main duct joins common bile
duct from liver
• Sphincter of Oddi on major
duodenal papilla
• Opens 4" below pyloric
sphincter
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Histology of the Pancreas
• Acini- dark clusters
– 99% of gland
– produce pancreatic juice
• Islets of Langerhans
– 1% of gland
– pale staining cells
– produce hormones
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Pancreas - Overview
• Pancreatic juice contains enzymes that digest starch
(pancreatic amylase), proteins (trypsin, chymotrypsin, and
carboxypeptidase), fats (pancreatic lipase), and nucleic
acids (ribonuclease and deoxyribonuclease).
• It also contains sodium bicarbonate which converts the acid
stomach contents to a slightly alkaline pH (7.1-8.2), halting
stomach pepsin activity and promoting activity of pancreatic
enzymes.
• Inflammation of the pancreas is called pancreatitis and can
result in trypsin beginning to digest pancreatic cells.
• Pancreatic cancer is nearly always fatal and in the fourth
most common cause of cancer death in the United States.
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Composition and Functions of Pancreatic Juice
• 1 & 1/2 Quarts/day at pH of 7.1 to 8.2
• Contains water, enzymes & sodium bicarbonate
• Digestive enzymes
– pancreatic amylase, pancreatic lipase, proteases
– trypsinogen---activated by enterokinase (a brush
border enzyme)
– chymotrypsinogen----activated by trypsin
– procarboxypeptidase---activated by trypsin
– proelastase---activated by trypsin
– trypsin inhibitor---combines with any trypsin
produced inside pancreas
– ribonuclease----to digest nucleic acids
– deoxyribonuclease
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Pancreatitis
• Pancreatitis---inflammation of the pancreas occurring with
the mumps
• Acute pancreatitis---associated with heavy alcohol intake or
biliary tract obstruction
– result is patient secretes trypsin in the pancreas & starts
to digest himself
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Regulation of Pancreatic Secretions
• Secretin
– acidity in intestine
causes increased
sodium bicarbonate
release
• GIP
– fatty acids & sugar
causes increased insulin
release
• CCK
– fats and proteins cause
increased digestive
enzyme release
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LIVER AND GALLBLADDER
• The liver is the heaviest gland in the body and the second
largest organ in the body after the skin.
• Anatomy of the Liver and Gallbladder
• The liver is divisible into left and right lobes, separated by
the falciform ligament. Associated with the right lobe are the
caudate and quadrate lobes (Figure 24.14).
• The gallbladder is a sac located in a depression on the
posterior surface of the liver (Figure 24.14).
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Anatomy of the Liver and Gallbladder
• Liver
– weighs 3 lbs.
– below diaphragm
– right lobe larger
– gallbladder on right
lobe
– size causes right
kidney to be lower
than left
• Gallbladder
– fundus, body &
neck
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Histology of
the Liver Introduction
• Hepatocytes arranged in
lobules
• Sinusoids in between
hepatocytes are blood-filled
spaces
• Kupffer cells phagocytize
microbes & foreign matter
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Histology of the Liver
• The lobes of the liver are made up of lobules that contain
hepatic cells (liver cells or hepatocytes), sinusoids, stellate
reticuloendothelial (Kupffer’s) cells, and a central vein
(Figure 24.15).
• Bile is secreted by hepatocytes.
• Bile passes into bile canaliculi to bile ducts to the right and
left hepatic ducts which unite to form the common hepatic
duct (Figure 24.14).
• Common hepatic duct joins the cystic duct to form the
common bile duct which enters the hepatopancreatic
ampulla.
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Histology of the Gallbladder
•
•
•
•
Simple columnar epithelium
No submucosa
Three layers of smooth muscle
Serosa or visceral peritoneum
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Application
• Jaundice is a yellowish coloration of the sclera, skin, and
mucous membranes due to a buildup of bilirubin. The main
categories of jaundice are prehepatic, hepatic, and
enterohepatic.
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Blood Supply
• The liver receives a double supply of blood from the hepatic
artery and the hepatic portal vein. All blood eventually
leaves the liver via the hepatic vein (Figure 24.16).
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Blood Supply to the Liver • Hepatic portal vein
– nutrient rich blood
from stomach, spleen
& intestines
• Hepatic artery from
branch off the aorta
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Flow of Fluids Within the Liver
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Bile - Overview
• Hepatic cells (hepatocytes) produce bile that is transported by a duct
system to the gallbladder for concentration and temporary storage.
• Bile is partially an excretory product (containing components of worn-out
red blood cells) and partially a digestive secretion.
• Bile’s contribution to digestion is the emulsification of triglycerides.
• The fusion of individual crystals of cholesterol is the beginning of 95% of
all gallstones. Gallstones can cause obstruction to the outflow of bile in
any portion of the duct system. Treatment of gallstones consists of using
gallstone-dissolving drugs, lithotripsy, or surgery.
• The liver also functions in carbohydrate, lipid, and protein metabolism;
removal of drugs and hormones from the blood; excretion of bilirubin;
synthesis of bile salts; storage of vitamins and minerals; phagocytosis;
and activation of vitamin D.
• In a liver biopsy a sample of living liver tissue is removed to diagnose a
number of disorders.
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Pathway of Bile
Secretion
• Bile capillaries
• Hepatic ducts connect to form common hepatic duct
• Cystic duct from gallbladder & common hepatic duct join to form
common bile duct
• Common bile duct & pancreatic duct empty into duodenum
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Bile Production
• One quart of bile/day is secreted by the liver
– yellow-green in color & pH 7.6 to 8.6
• Components
– water & cholesterol
– bile salts = Na & K salts of bile acids
– bile pigments (bilirubin) from hemoglobin molecule
• globin = a reuseable protein
• heme = broken down into iron and bilirubin
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Regulation of Bile Secretion
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Liver Functions--Carbohydrate Metabolism
• Turn proteins into glucose
• Turn triglycerides into glucose
• Turn excess glucose into glycogen & store
in the liver
• Turn glycogen back into glucose as needed
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Liver Functions --Lipid Metabolism
• Synthesize cholesterol
• Synthesize lipoproteins----HDL and
LDL(used to transport fatty acids in
bloodstream)
• Stores some fat
• Breaks down some fatty acids
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Liver Functions--Protein Metabolism
• Deamination = removes NH2 (amine group) from
amino acids so can use what is left as energy source
• Converts resulting toxic ammonia (NH3) into urea for
excretion by the kidney
• Synthesizes plasma proteins utilized in the clotting
mechanism and immune system
• Convert one amino acid into another
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Other Liver Functions
• Detoxifies the blood by removing or altering drugs & hormones(thyroid &
estrogen)
• Removes the waste product--bilirubin
• Releases bile salts help digestion by emulsification
• Stores fat soluble vitamins-----A, B12, D, E, K
• Stores iron and copper
• Phagocytizes worn out blood cells & bacteria
• Activates vitamin D (the skin can also do this with 1 hr of sunlight a
week)
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Summary of Digestive Hormones
• Gastrin
– stomach, gastric & ileocecal sphincters
• Gastric inhibitory peptide--GIP
– stomach & pancreas
• Secretin
– pancreas, liver & stomach
• Cholecystokinin--CCK
– pancreas, gallbladder, sphincter of Oddi, &
stomach
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SMALL INTESTINE
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Introduction
• The major events of digestion and absorption occur in the
small intestine.
• The small intestine extends from the pyloric sphincter to the
ileocecal sphincter.
• Anatomy of the Small Intestine
• The small intestine is divided into the duodenum, jejunum,
and ileum (Figure 24.17).
• Projections called circular folds, or plicae circularies, are
permanent ridges in the mucosa that enhance absorption by
increasing surface area and causing chyme to spiral as it
passes through the small intestine (Figure 24.17).
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Anatomy of the Small Intestine
• 20 feet long----1 inch in diameter
• Large surface area for majority of absorption
• 3 parts
– duodenum---10 inches
– jejunum---8 feet
– ileum---12 feet
• ends at ileocecal valve
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• plica circularis
– permanent ½ inch tall folds that
contain part of submucosal
layer
– not found in lower ileum
– can not stretch out like rugae in
stomach
• villi
– 1 Millimeter tall
– Core is lamina propria of
mucosal layer
– Contains vascular capillaries
and lacteals(lymphatic
capillaries)
• microvilli
– cell surface feature known as
brush border
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small intestine
105
Small Intestine - Overview
• The mucosa forms fingerlike villi which increase the surface area of the
epithelium available for absorption and digestion (Figure 24.18a).
• Embedded in the villus is a lacteal (lymphatic capillary) for fat
absorption.
• The cells of the mucosal epithelium include absorptive cells, goblet cells,
enteroendocrine cells, and Paneth cells (Figure 24.18b).
• The free surface of the absorptive cells feature microvilli, which increase
the surface area (Figure 24.19d). They form the brush border which also
contains several enzymes.
• The mucosa contains many cavities lined by glandular epithelium. These
cavities form the intestinal glands (crypts of Lieberkuhn).
• The submucosa of the duodenum contains duodenal (Brunner’s) glands
which secrete an alkaline mucus that helps neutralize gastric acid in
chyme. The submucosa of the ileum contains aggregated lymphatic
nodules (Peyer’s patches) (Figure 24.19a).
• The muscularis consists of 2 layers of smooth muscles
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Histology of Small Intestine
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Functions of Microvilli
•
•
•
•
Absorption and digestion
Digestive enzymes found at cell surface on microvilli
Digestion occurs at cell surfaces
Significant cell division within intestinal glands
produces new cells that move up
• Once out of the way---rupturing and releasing their
digestive enzymes & proteins
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Cells of Intestinal Glands
• Absorptive cell
• Goblet cell
• Enteroendocrine
– secretin
– cholecystokinin
– gastric inhibitory
peptide
• Paneth cells
– secretes lysozyme
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Goblet Cells of GI epithelium
Unicellular glands
that are part of
simple columnar
epithelium
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Roles of Intestinal Juice & Brush-Border Enzymes
• Submucosal layer has duodenal glands
– secretes alkaline mucus
• Mucosal layer contains intestinal glands = Crypts of
Lieberkuhn(deep to surface)
– secretes intestinal juice
• 1-2 qt./day------ at pH 7.6
– brush border enzymes
– paneth cells secrete lysozyme kills bacteria
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Intestinal Juice and Brush Border Enzymes
• Intestinal juice provides a vehicle for absorption of
substances from chyme as they come in contact with the
villi.
• Some intestinal enzymes (brush border enzymes) break
down foods inside epithelial cells of the mucosa on the
surfaces of their microvilli.
• Some digestion also occurs in the lumen of the small
intestine.
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Mechanical Digestion in the Small Intestine
• Segmentation, the major movement of the small intestine, is
a localized contraction in areas containing food.
• Peristalsis propels the chyme onward through the intestinal
tract.
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Mechanical Digestion in the Small Intestine
• Weak peristalsis in
comparison to the
stomach---chyme remains
for 3 to 5 hours
• Segmentation---local
mixing of chyme with
intestinal juices---sloshing
back & forth
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Chemical Digestion in the Small Intestine
• Carbohydrates are broken down into monosaccharides for
absorption.
• Intestinal enzymes break down starches into maltose,
maltotriose, and alpha-dextrins (pancreatic amylase); alphadextrins into glucose (alphadestrinase); maltose to glucose
(maltase); sucrose to glucose and fructose (sucrase); and
lactose to glucose and galactose (lactase).
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Chemical Digestion in Small Intestine
• Chart page 853--groups enzymes by region where they are
found
• Need to trace breakdown of nutrients
– carbohydrates
– proteins
– lipids
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Review: Digestion of Carbohydrates
•
•
•
•
Mouth---salivary amylase
Esophagus & stomach---nothing happens
Duodenum----pancreatic amylase
Brush border enzymes (maltase, sucrase & lactose)
act on disaccharides
– produces monosaccharides--fructose, glucose &
galactose
– lactose intolerance (no enzyme; bacteria ferment
sugar)--gas & diarrhea
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Lactose Intolerance
• Mucosal cells of small intestine fail to produce lactase
– essential for digestion of lactose sugar in milk
– undigested lactose retains fluid in the feces
– bacterial fermentation produces gases
• Symptoms
– diarrhea, gas, bloating & abdominal cramps
• Dietary supplements are helpful
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Review: Digestion of Proteins
• Stomach
– HCl denatures or unfolds proteins
– pepsin turns proteins into peptides
• Pancreas
– digestive enzymes---split peptide bonds between different
amino acids
– brush border enzymes-----aminopeptidase or dipeptidase
• enzymes break peptide bonds that attach terminal amino
acids to carboxyl ends of peptides (carboxypeptidases)
• enzymes break peptide bonds that attach terminal amino
acids to amino ends of peptides (aminopeptidases)
– enzymes split dipeptides to amino acids (dipeptidase)
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Review: Digestion of Lipids
• Mouth----lingual lipase
• Most lipid digestion, in an adult, occurs in the
small intestine.
– emulsification by bile of globules of
triglycerides
– pancreatic lipase---splits triglycerides into fatty
acids & monoglycerides
– no enzymes in brush border
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Digestion of Nucleic Acids
• Nucleic acids are broken down into nucleotides for absorption.
• Pancreatic juice contains 2 nucleases
– ribonuclease which digests RNA
– deoxyribonuclease which digests DNA
• Nucleotides produced are further digested by brush border
enzymes (nucleosidease and phosphatase)
– pentose, phosphate & nitrogenous bases
• Absorbed by active transport
A summary of digestive enzymes in terms of source,
substrate acted on, and product is presented in Table
24.5.
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Regulation of Secretion & Motility
• Enteric reflexes that respond to presence of chyme
– increase intestinal motility
– VIP (vasoactive intestinal polypeptide) stimulates
the production of intestinal juice
– segmentation depends on distention which sends
impulses to the enteric plexus & CNS
• distention produces more vigorous peristalsis
• 10 cm per second
• Sympathetic impulses decrease motility
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Regulation of Secretion & Motility
• Enteric reflexes that respond to presence of chyme
– increase intestinal motility
– VIP (vasoactive intestinal polypeptide) stimulates
the production of intestinal juice
– segmentation depends on distention which sends
impulses to the enteric plexus & CNS
• distention produces more vigorous peristalsis
• 10 cm per second
• Sympathetic impulses decrease motility
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Absorption in the Small Intestine
• Absorption is the passage of the end products of digestion
from the GI tract into blood or lymph and occurs by diffusion,
facilitated diffusion, osmosis, and active transport.
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Absorption in Small Intestine
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Where will the absorbed nutrients go?
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Absorption of Monosaccharides
• Essentially all carbohydrates are absorbed as
monosaccharides.
• They are absorbed into blood capillaries (Figure 24.19 a,b).
• Absorption of Amino Acids, Dipeptides, and Tripeptides
• Most proteins are absorbed as amino acids by active
transport processes.
• They are absorbed into the blood capillaries in the villus
(Figure 24.22a,b).
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Absorption of Monosaccharides
• Absorption into epithelial cell
– glucose & galactose----sodium symporter(active transport)
– fructose-----facilitated diffusion
• Movement out of epithelial cell into bloodstream
– by facilitated diffusion
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Absorption of Amino Acids & Dipeptides
• Absorption into epithelial cell
– active transport with Na+ or H+ ions (symporters)
• Movement out of epithelial cell into blood
– diffusion
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Absorption of Lipids - Overview
• Dietary lipids are all absorbed by simple diffusion.
• Long-chain fatty acids and monoglycerides are absorbed as part of
micelles, resynthesized to triglycerides, and formed into protein-coated
spherical masses called chylomicrons.
• Chylomicrons are taken up by the lacteal of a villus.
• From the lacteal they enter the lymphatic system and then pass into the
cardiovascular system, finally reaching the liver or adipose tissue
(Figure 24.23, 24.22a).
• The plasma lipids - fatty acids, triglycerides, cholesterol - are insoluble in
water and body fluids.
• In order to be transported in blood and utilized by body cells, the lipids
must be combined with protein transporters called lipoproteins to make
them soluble.
• The combination of lipid and protein is referred to as a lipoprotein.
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Absorption of Lipids
•
•
•
•
•
Small fatty acids enter cells & then blood by simple diffusion
Larger lipids exist only within micelles (bile salts coating)
Lipids enter cells by simple diffusion leaving bile salts behind in gut
Bile salts reabsorbed into blood & reformed into bile in the liver
Fat-soluble vitamins are enter cells since were within micelles
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Absorption of Lipids
• Inside epithelial cells fats are rebuilt and coated with protein to form
chylomicrons
•
Chylomicrons leave intestinal cells by exocytosis into a lacteal
– travel in lymphatic system to reach veins near the heart
– removed from the blood by the liver and fat tissue
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Absorption of Electrolytes
• Many of the electrolytes absorbed by the small intestine come
from gastrointestinal secretions and some are part of digested
foods and liquids.
• Enter epithelial cells by diffusion & secondary active transport
– sodium & potassium move = Na+/K+ pumps (active transport)
– chloride, iodide and nitrate = passively follow
– iron, magnesium & phosphate ions = active transport
• Intestinal Ca+ absorption requires vitamin D & parathyroid
hormone
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Absorption of Vitamins
• Fat-soluble vitamins (A, D, E, and K) are included along
with ingested dietary lipids
– travel in micelles & are absorbed by simple diffusion
• Water-soluble vitamins (B and C)
– absorbed by diffusion
• B12 combines with intrinsic factor before it is transported
into the cells
– receptor mediated endocytosis
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Absorption of Water
• Figure 24.24 reviews the fluid input to the GI tract.
• All water absorption in the GI tract occurs by osmosis from
the lumen of the intestines through epithelial cells and into
blood capillaries.
• The absorption of water depends on the absorption of
electrolytes and nutrients to maintain an osmotic balance
with the blood.
• Table 24.5 summarizes the digestive and absorptive
activities of the small intestine and associated accessory
structures.
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Absorption of Water
• 9 liters of fluid dumped into GI
tract each day
• Small intestine reabsorbs 8 liters
• Large intestine reabsorbs 90% of
that last liter
• Absorption is by osmosis through
cell walls into vascular capillaries
inside villi
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LARGE INTESTINE
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Anatomy of the Large Intestine (Figure 24.25b)
• The large intestine (colon) extends from the ileocecal
sphincter to the anus.
• Its subdivisions include the cecum, colon, rectum, and anal
canal (Figure 24.25a).
• Hanging inferior to the cecum is the appendix.
– Inflammation of the appendix is called appendicitis.
– A ruptured appendix can result in gangrene or peritonitis,
which can be life-threatening conditions.
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Anatomy of
Large Intestine
•
•
•
•
5 feet long by 2½ inches in diameter
Ascending & descending colon are retroperitoneal
Cecum & appendix
Rectum = last 8 inches of GI tract anterior to the sacrum &
coccyx
• Anal canal = last 1 inch of GI tract
– internal sphincter----smooth muscle & involuntary
– external sphincter----skeletal muscle & voluntary control
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Appendicitis
• Inflammation of the appendix due to blockage of the
lumen by chyme, foreign body, carcinoma, stenosis, or
kinking
• Symptoms
– high fever, elevated WBC count, neutrophil count
above 75%
– referred pain, anorexia, nausea and vomiting
– pain localizes in right lower quadrant
• Infection may progress to gangrene and perforation
within 24 to 36 hours
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Histology of the Large Intestine
• The mucosa of the large intestine has no villi or permanent
circular folds. It does have a simple columnar epithelium
with numerous globlet cells (Figure 24.26).
• The muscularis contains specialized portions of the
longitudinal muscles called taeniae coli, which contract and
gather the colon into a series of pouches called haustra
(Figure 24.25a).
• Polyps in the colon are generally slow growing and benign.
They should be removed because they may become
cancerous.
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Histology of
Large
Intestine
• Mucosa
– smooth tube -----no villi or plica
– intestinal glands fill the the mucosa
– simple columnar cells absorb water &
goblet cells secrete mucus
• Submucosal & mucosa contain lymphatic
nodules
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Histology of Large Intestine
• Muscular layer
– internal circular layer is
normal
– outer longitudinal muscle
• taeniae coli = shorter
bands
• haustra (pouches)
formed
• epiploic appendages
• Serosa = visceral peritoneum
• Appendix
– contains large amounts of
lymphatic tissue
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Mechanical Digestion in Large Intestine
• Mechanical movements of the large intestine include
haustral churning, peristalsis, and mass peristalsis.
• Peristaltic waves (3 to 12 contractions/minute)
– haustral churning----relaxed pouches are filled from
below by muscular contractions (elevator)
– gastroilial reflex = when stomach is full, gastrin hormone
relaxes ileocecal sphincter so small intestine will empty
and make room
– gastrocolic reflex = when stomach fills, a strong
peristaltic wave moves contents of transverse colon into
rectum
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Chemical Digestion in Large Intestine
• No enzymes are secreted only mucous
• Bacteria ferment
– undigested carbohydrates into carbon dioxide &
methane gas
– undigested proteins into simpler substances
(indoles)----odor
– turn bilirubin into simpler substances that produce
color
• Bacteria produce vitamin K and B in colon
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Absorption & Feces Formation in the Large
Intestine
• Some electrolytes---Na+ and Cl• After 3 to 10 hours, 90% of H2O has been removed from
chyme
• Feces are semisolid by time reaches transverse colon
• Feces = dead epithelial cells, undigested food such as
cellulose, bacteria (live & dead)
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Absorption and Feces Formation in the Large
Intestine
• The large intestine absorbs water, electrolytes, and some
vitamins.
• Feces consist of water, inorganic salts, sloughed-off
epithelial cells, bacteria, products of bacterial
decomposition, and undigested parts of food.
• Although most water absorption occurs in the small
intestine, the large intestine absorbs enough to make it an
important organ in maintaining the body’s water balance.
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Defecation Reflex
• The elimination of feces from the rectum is called
defecation.
• Defecation is a reflex action aided by voluntary contractions
of the diaphragm and abdominal muscles. The external anal
sphincter can be voluntarily controlled (except in infants) to
allow or postpone defecation.
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Defecation
• Gastrocolic reflex moves feces into
rectum
• Stretch receptors signal sacral
spinal cord
• Parasympathetic nerves contract
muscles of rectum & relax internal
anal sphincter
• External sphincter is voluntarily
controlled
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Defecation Problems
• Diarrhea = chyme passes too quickly through intestine
– H20 not reabsorbed
• Constipation--decreased intestinal motility
– too much water is reabsorbed
– remedy = fiber, exercise and water
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Applications
• Dietary fiber may be classified as insoluble (does not dissolve in water)
and soluble (dissolves in water).
– Both types affect the speed of food passage through the GI tract
• Insoluble fiber
– woody parts of plants (wheat bran, veggie skins)
– may help protect against colon cancer
• Soluble fiber
– gel-like consistency = beans, oats, citrus white parts, apples
– lowers blood cholesterol by preventing reabsorption of bile
salts so liver has to use cholesterol to make more
• Colonoscoy is the visual examination of the lining of the colon using an
elongated, flexible, fiberoptic endoscope.
• Occult blood test is to screen for colorectal cancer.
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Review
• Table 24.6 summarizes the digestive activities in the large
intestine while Table 24.7 summarizes the organs of the
digestive system and their functions.
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PHASES OF DIGESTION
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Regulation of Gastric Secretion and Motility
• Cephalic phase
• Gastric phase
• Intestinal phase
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Gastric Secretion and Motility
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Cephalic phase
• The cephalic phases is initiated by sensory receptors in the
head; prepares the mouth and stomach for food that is
about to be eaten.
• Cerebral cortex =sight, smell, taste & thought
– stimulate parasympathetic nervous system
• The facial and glossopharyngeal nerves stimulate the
salivary glands.
• Vagus nerve increases stomach muscle and glandular
activity
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Gastric Phase = “Stomach Working”
• Nervous control keeps stomach active
– stretch receptors & chemoreceptors provide information
– vigorous peristalsis and glandular secretions continue
– chyme is released into the duodenum
• Endocrine influences over stomach activity
– distention and presence of caffeine or protein cause G
cells secretion of gastrin into bloodstream
– gastrin hormone increases stomach glandular secretion
– gastrin hormone increases stomach churning and
sphincter relaxation
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Intestinal phase
• The intestinal phase begins when food enters the small intestine.
• Stretch receptors, fatty acids or sugar signals medulla
– sympathetic nerves slow stomach activity & increase intestinal
activity
– The enterogastric reflex inhibits gastric motility and increases the
contraction of the pyloric sphincter to decrease gastric emptying.
• Hormonal influences
– secretin stimulates the flow of pancreatic juice rich in bicarbonate,
and inhibits the secretion of gastric juice.
– cholecystokinin(CCK) decreases stomach emptying and stimulates
the secretion of pancreatic juice rich in digestive enzymes, and
increase the flow of bile
– gastric inhibitory peptide(GIP) decreases stomach secretions,
motility & emptying
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Absorption of Nutrients by the Stomach
•
•
•
•
Water especially if it is cold
Electrolytes
Some drugs (especially aspirin) & alcohol
Fat content in the stomach slows the passage of alcohol to the intestine
where absorption is more rapid
• Gastric mucosal cells contain alcohol dehydrogenase that converts some
alcohol to acetaldehyde-----more of this enzyme found in males than
females
• Females have less total body fluid that same size male so end up with
higher blood alcohol levels with same intake of alcohol
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Regulation of Gastric
Emptying - Review
• Release of chyme is regulated by neural and
hormonal reflexes
• Distention & stomach contents increase
secretion of gastrin hormone & vagal nerve
impulses
– stimulate contraction of esophageal
sphincter and stomach and relaxation of
pyloric sphincter
• Enterogastric reflex regulates amount
released into intestines
– distension of duodenum & contents of
chyme
– sensory impulses sent to the medulla
inhibit parasympathetic stimulation of the
stomach but increase secretion of
cholecystokinin and stimulate sympathetic
impulses
– inhibition of gastric emptying
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Vomiting (emesis)
• Forceful expulsion of contents of stomach & duodenum through
the mouth
• Cause
– irritation or distension of stomach
– unpleasant sights, general anesthesia, dizziness & certain
drugs
• Sensory input from medulla cause stomach contraction &
complete sphincter relaxation
• Contents of stomach squeezed between abdominal muscles
and diaphragm and forced through open mouth
• Serious because loss of acidic gastric juice can lead to alkalosis
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Other hormones
• Other hormones that have effects on the GI tract are motilin,
substance P, bombesin, vasoactive intestinal polypeptide
(VIP), gastrin-releasing peptide, and somatostatin.
• Table 24.8 summarizes the major hormones that control
digestion.
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DEVELOPMENT OF THE DIGESTIVE SYSTEM
• The endoderm of the primitive gut forms the epithelium and
glands of most of the gastrointestinal tract (Figure 24.12).
• The mesoderm of the primitive gut forms the smooth muscle
and connective tissue of the GI tract.
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Development of the Digestive System
• Endoderm forms primitive gut with help from the splanchnic mesoderm --resulting tube is made up of epithelial, glandular, muscle & connective
tissue
• Differentiates into foregut, midgut & hindgut
• Endoderm grows into the mesoderm to form salivary glands, liver,
gallbladder & pancreas
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Development of the Digestive System
• Stomodeum develops
into oral cavity
– oral membrane
ruptures
• Proctodeum develops
into anus
– cloacal membrane
ruptures
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Aging and the Digestive System
• Changes that occur
– decreased secretory mechanisms
– decreased motility
– loss of strength & tone of muscular tissue
– changes in neurosensory feedback
– diminished response to pain & internal stimuli
• Symptoms
– sores, loss of taste, peridontal disease, difficulty swallowing, hernia,
gastritis, ulcers, malabsorption, jaundice, cirrhosis, pancreatitis,
hemorrhoids and constipation
• Cancer of the colon or rectum is common
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Diseases of the GI Tract
•
•
•
•
•
•
Dental caries and periodontal disease
Peptic Ulcers
Diverticulitis
Colorectal cancer
Hepatitis
Anorexia nervosa
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DISORDERS: HOMEOSTATIC IMBALANCES
• Dental caries, or tooth decay, is started by acid-producing
bacteria that reside in dental plaque, act on sugars, and
demineralize tooth enamel and dentin with acid.
• Periodontal diseases are characterized by inflammation and
degeneration of the gingivae (gums), alveolar bone,
periodontal ligament, and cementum.
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DISORDERS: HOMEOSTATIC IMBALANCES
• Peptic ulcers are crater-like lesions that develop in the
mucous membrane of the GI tract in areas exposed to
gastric juice. The most common complication of peptic
ulcers is bleeding, which can lead to anemia if blood loss is
serious. The three well-defined causes of peptic ulcer
disease (PUD) are the bacterium Helicobacter pylori;
nonsteroidal anti-inflammatory drugs, such as aspirin; and
hypersecretion of HCl.
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DISORDERS: HOMEOSTATIC IMBALANCES
• Diverticula are saclike outpouchings of the wall of the colon
in places where the muscularis has become weak. The
development of diverticula is called diverticulosis.
Inflammation within the diverticula, known as diverticulitis,
may cause pain, nausea, vomiting, and either constipation
or an increased frequency of defecation. High fiber diets
help relieve the symptoms.
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DISORDERS: HOMEOSTATIC IMBALANCES
• Hepatitis is an inflammation of the liver and can be caused
by viruses, drugs, and chemicals, including alcohol.
• Hepatitis A (infectious hepatitis) is caused by hepatitis A
virus and is spread by fecal contamination. It does not
cause lasting liver damage.
• Hepatitis B is caused by hepatitis B virus and is spread
primarily by sexual contact and contaminated syringes and
transfusion equipment. It can produce cirrhosis and possibly
cancer of the liver. Vaccines are available to prevent
hepatitis B infection.
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DISORDERS: HOMEOSTATIC IMBALANCES
• Hepatitis C is caused by the hepatitis C virus. It is clinically
similar to hepatitis B and is often spread by blood
transfusions. It can cause cirrhosis and possibly liver
cancer.
• Hepatitis D is caused by hepatitis D virus. It is transmitted
like hepatitis B and, in fact, a person must be co-infected
with hepatitis B before contracting hepatitis D. It results in
severe liver damage and has a high fatality rate.
• Hepatitis E is caused by hepatitis E virus and is spread like
hepatitis A. It is responsible for a very high mortality rate in
pregnant women.
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DISORDERS: HOMEOSTATIC IMBALANCES
• Anorexia nervosa is a chronic disorder characterized by
self-induced weight loss, body-image and other perceptual
disturbances, and physiologic changes that result from
nutritional depletion. The disorder is found predominantly in
young, single females and may be inherited. Individuals may
become emaciated and may ultimately die of starvation or
one of its complications. Treatment consists of
psychotherapy and dietary regulation.
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